EP4332831A1 - Flat metal product with position code pattern - Google Patents

Abstract

A flat metal product (100) is described which is provided on at least one flat side (100A) with a position code pattern made up of an arrangement of distributed dots.

Description

The invention relates to a flat metal product which is provided with a marking containing a code on at least one flat side.

It is known to apply product markings to flat metal products in the form of labels, stickers or optically readable codes (e.g. QR codes or bar codes) that identify the product.

Such markings can detach from the product, are only present as discrete markings in certain places and are often annoying due to their visibility on the product. They can also become unreadable over the life of the product.

Out of EP 3 562 603 A1 a coil made of a wound metal strip is known, which is provided with a marking in the form of an information track on one flat side. The information track makes it possible to assign a section of tape separated from a coil to the coil and to determine the position of the separated section of tape in the coil.

One task on which the invention is based can be seen in creating a different metal band marking. In particular, the disadvantages of the previously known metal band markings should be overcome. Furthermore, the invention aims to specify methods for providing and/or retrieving information based on a metal band marking.

The problem on which the invention is based is solved by the features of the independent claims. Examples of embodiments and further training are the subject of the dependent claims.

Accordingly, a flat metal product is provided on at least one flat side with a position code pattern made up of an arrangement of distributed dots.

Dot markings can be applied in such a way that they are invisible or barely visible to the viewer or end customer. The use of dots as markings therefore also enables the position code pattern to be applied to a visible side of the flat metal product without appearing disruptive. Furthermore, as will be described in more detail below, large areas or the entire flat side of the flat metal product can be provided with the position code pattern, so that the position code pattern or a part of it can still be present on components cut or punched out of the flat metal product can. The points can be circular, but all other shapes such as rectangles or squares are possible.

In addition, the position code pattern remains detectable and decodable even if part of the flat metal product is covered, for example by installation, or the flat metal product is subjected to forming. The position code pattern can have a high resistance to aging and - unlike labels or stickers - can be inextricably linked to the flat metal product.

A position code pattern as a product marking also enables the provision and/or retrieval of a wide range of information, either from the manufacturer of the Flat metal product or can be assigned to the flat metal product by the customer or user.

The flat metal product can be, for example, a metal strip or a metal plate or a component containing at least one metal plate and another layer of material. In particular, multi-layer sandwich panels or hybrid components (which are constructed, for example, from a shaped sheet metal component and a fiber-reinforced plastic material attached to it) can be used.

The flat metal product can have a coating on the flat side provided with the position code pattern. It is possible for the position code pattern to be implemented in the coating or applied to the coating. There is also the possibility of implementing the position code pattern as a structural pattern (e.g. in the form of a dot relief) below the coating, whereby it can be detected through the coating.

The dots can be applied, for example, by a printing process, i.e. printing the flat metal product with the arrangement of distributed dots.

If the position code pattern is applied essentially over the entire surface to the flat side of the flat metal product, parts are still provided with the position code even if the flat metal product is shredded. This makes it possible to determine the information assigned to the position code pattern even on parts (e.g. blanks or scrap parts) of the flat metal product. Furthermore, the aging resistance is increased, since if the position code pattern is present over a large area or essentially over the entire area, the probability the fact that parts of the position code pattern are still intact after the pattern has deteriorated due to aging is increased.

The array of distributed dots may have a nominal grid spacing equal to or greater than 0.1 cm, 0.5 cm, 1 cm, 2 cm or 5 cm, i.e., it may be compared to known position code patterns from an array of distributed dots If necessary, a significantly larger grid spacing can be selected.

The position code pattern can uniquely code the flat metal product. In particular, the position code pattern can make the flat metal product clearly identifiable and/or contain further information about the flat metal product, such as data on the manufacturing process, the materials, their chemical compositions, logistics data, installation data, data regarding the maintenance history, recycling data of the flat metal product or data for marketing purposes . In particular, the position code pattern can be designed in such a way that flat metal products made from a metal strip are individually identified and/or uniquely assigned to the original position of the flat metal product in the metal strip.

The position code pattern may encode at least one position on an imaginary surface. By capturing the position code pattern, that position can be decoded and information associated with the decoded position can be retrieved.

The position code pattern may be formed in such a way that the distances between adjacent points vary and the variation of the Distances of a plurality of neighboring points uniquely encode the position on the imaginary surface.

Furthermore, a method for retrieving information in connection with a flat metal product is provided, in which a flat side of the flat metal product is provided with a position code pattern made up of an array of distributed dots. To determine a position on an imaginary surface, at least part of the position code pattern is detected and decoded. The method further includes retrieving information associated with the determined position.

For example, the at least part of the position code pattern can be captured optically using a camera or a reading device. The decoding of the captured part of the position code pattern can be carried out using application software of the reading device. For example, the reading device can be a mobile device, in particular a smartphone or a tablet computer.

In addition to the information already mentioned about the flat metal product, which can be contained in the information retrieved, the information retrieved can also contain information about the intended use and/or location of use of the flat metal product and/or information provided by the user of the flat metal product. This information can, but does not have to be, assigned to the position code pattern by the manufacturer of the flat metal product. It is also possible that, for example, the intended use and/or the place of use of the flat metal product are assigned to the position code pattern by the user of the flat metal product (eg by the manufacturer's customer).

A method for providing information in connection with a flat metal product includes providing information that is associated with a determinable position. The flat metal product is provided on at least one flat side with a position code pattern made up of an arrangement of distributed points, with detection and decoding of at least part of the position code pattern enabling the determination of a position on an imaginary surface.

The information can be stored on a server and accessed via addressing depending on a determinable position via a network, in particular the Internet. Another possibility is that the information is stored in a memory of a reading device for detecting and decoding at least part of the position code pattern and can be retrieved from the memory via addressing depending on a determinable position.

• Figur 1A zeigt ein Beispiel eines Flachmetallprodukts in Längsschnittdarstellung.
• Figur 1B zeigt ein Beispiel eines Flachmetallprodukts in Draufsicht auf die mit dem Positionscode-Muster versehene Flachseite.
• Figur 2 zeigt ein Beispiel eines beschichteten Flachmetallproduktes sowie verschiedene Möglichkeiten der Realisierung eines Positionscode-Musters aus einer Anordnung von verteilten Punkten am Flachmetallprodukt.
• Figur 3 zeigt ein Teil des Positionscode-Musters am Flachmetallprodukt.
• Figur 4 dient zur Erläuterung eines Verfahrens zum Abruf von Information im Zusammenhang mit einem Flachmetallprodukt und/oder eines Verfahrens zur Bereitstellung von Information im Zusammenhang mit einem Flachmetallprodukt.

Examples and possible embodiments of the invention are explained in more detail below with reference to the drawings.

• Figure 1A shows an example of a flat metal product in a longitudinal section.
• Figure 1B shows an example of a flat metal product in a top view of the flat side provided with the position code pattern.
• Figure 2 shows an example of a coated flat metal product as well as various possibilities for realizing a position code pattern from an arrangement of distributed points on the flat metal product.
• Figure 3 shows part of the position code pattern on the flat metal product.
• Figure 4 serves to explain a method for retrieving information in connection with a flat metal product and / or a method for providing information in connection with a flat metal product.

Terms such as "applying" or "applying" as well as similar terms (e.g. "applied" or "applied") in this description are not to be understood as meaning that the applied or applied layers are in direct contact with the surface on which they are applied or must be applied. There may be intervening elements or layers between the "applied" or "applied" elements or layers and the underlying surface. However, the above-mentioned or similar terms in this disclosure may also have the specific meaning that the elements or layers are in direct contact with the underlying surface, i.e., that there are no intervening elements or layers.

The term "over" as used in reference to an element or layer of material formed or applied "over" a surface may be used herein to mean that the element or layer of material is "indirectly on" the Surface is attached, wherein intermediate elements or layers may be present between the surface and the element or layer of material. However, the term "over" may also have the specific meaning that the element or layer of material that is applied or applied "over" a surface, "directly on", ie in direct contact with the surface in question. The same applies to similar terms such as "above", "under", "underneath", etc.

Figures 1A and 1B show an exemplary flat metal product 100 in a schematic longitudinal section or in a top view. The flat metal product 100 can be, for example, a metal strip or a section of strip separated from the metal strip, for example a metal circuit board. Such flat metal products are known in a variety of designs and can be used in a wide variety of areas of application.

For example, metal plates (mostly steel plates) cut out of metal strips are used as cladding in buildings, for example as facade or roof cladding. In addition, flat metal products 100 are found, for example, in the household appliance industry, in particular the so-called white goods, in building technology, in particular doors, door frames, lights, ventilation technology and electrical housings, as well as electrical strips for the construction of electrical cores, as body components for motor vehicles or in a variety of other industrial areas, such as for example the construction of pipelines, application. Another area of application can be found in the area of storage technology, especially for high-bay warehouses.

In many cases it is helpful to provide such flat metal products 100 with markings on the surface through which product data and/or further information can be accessed.

The flat metal product 100 has two flat sides 100A and 100B. According to the present disclosure, the flat metal product 100 is on at least one flat side 100A with a Position code pattern from an arrangement of distributed points P. An excerpt of such a position code pattern is in Figure 1B designated with the reference number 150 and shown in an enlarged view.

A position code pattern 150 contains one or more position codes. A position code uniquely encodes a position by means of which (after decoding) information associated with that position can be obtained. This means that the information available via the position code is not encoded directly in the position code, but is linked to the position encoded by the position code.

In general, a wide variety of position codes or position code patterns 150 can be used, which are constructed from an arrangement of distributed points. Special position code patterns 150 from an arrangement of distributed points are described in more detail below.

The flat metal product 100 can be designed with a coating 120 on the flat side 100A provided with the position code pattern 150. For example, it can be constructed from a metal strip or a metal circuit board 110, over which the coating 120 is arranged. The coating 120 can be, for example, a coating 120 that is produced by galvanizing or aluminizing, for example hot-dip galvanizing or electrolytic galvanizing or hot-dip aluminizing. In particular, the coating 120 can be an organic coating and/or a paint system. Organically coated steel strips are known, for example, under the brand name “colofer ^® ”.

In general, various deposition methods, such as vacuum deposition methods, can be used to produce the coating 120. For example, the coating 120 can be produced using PVD (Physical Vapor Deposition), CVD (Chemical Vapor Deposition) or sputtering. Furthermore, dip coating processes, electroplating processes, roller applications or spray processes can be used.

The coating 120 can be multi-layered, for example. For example, in the case of a paint coating, a lower coating layer can be made up of a chromate-free primer and an upper coating layer can be made up of a top coat (for example colofer ^® top coat).

The coating 120 can serve to give the flat metal product (eg steel panel) 100 high corrosion resistance and UV resistance. In addition, the coating 120 can enable constant weathering stability over the lifespan of the flat metal product 100, so that it can be used, for example, as a building facade and/or as a roof covering. Furthermore, the coating 120 can be provided, for example, on the visible side of the flat metal product (related to the later use of the same), that is, for example, on the outside of a metal plate used as a facade or roof covering, which is visible to the viewer. The coating 120 can be in a variety of colors. Organic paint systems, such as colofer ^® paints, fulfill these properties.

The position code pattern 150 can be applied to a coated flat metal product 100, for example on the coating 120 (eg position code pattern 150_1) or can be implemented in the coating 120 (eg position code pattern 150_2). In particular, in this case, the position code pattern 150 can be exposed on the surface of the coating 120 (position code pattern 150_3). In the case of a multi-layer coating 120, the points P of the position code pattern 150 can be provided in the top layer 122 of the coating 120 (e.g. a colofer ^® coating or galvanizing) (position code pattern 150_4) and can be exposed on the surface, for example. They can also be applied to the top layer 122 of the coating 122 (like position code pattern 150_1). In addition, it is also possible to realize the position code pattern 150 as a structural pattern below the coating 120 (eg position code pattern 150_5), whereby it can be detected through the coating 120, for example optically or in another way. In the position code pattern 150_5, the points P can be implemented, for example, as a structure (topography) of the surface of the coating 120.

For example, the position code pattern 150 can be detected optically or magnetically or using radar or X-ray technology. The points P of the position code pattern 150 can, for example, have a different color than their surroundings, which enables optical detectability, for example.

If the points P of the position code pattern 150 have a different color than their surroundings, the color of the points P can only deviate slightly from the surrounding color, so that this deviation can hardly be recognized by the viewer. Furthermore, it is possible to use an infrared-sensitive paint or a black light varnish for the points P, as a result of which the optical impression of the flat metal product 100 is not or not significantly changed by the points P.

Additionally or alternatively, the points P may have a different reflectivity outside the visible light spectrum than their surroundings. This or other implementations (for example a magnetic position code pattern 150 or one that can be detected using radar or X-ray technology) make it possible for the position code pattern 150 not to be visible or practically not visible to a viewer, so that it does not affect the optical impression of the component barely changed.

On the other hand, for many applications, a visible dot pattern on a visible surface is not a problem, since it may even enhance the appearance of the flat metal product 100 and/or cannot be resolved by the viewer from a distance or at a usual viewing distance.

In all cases, the flat side 100A can be provided with the position code pattern 150 essentially over its entire surface. This means that the position code pattern 150 can extend continuously in the longitudinal and transverse dimensions essentially over the entire flat side 100A or it is also possible for the position code pattern 150 to be constructed from sub-pattern areas spaced apart from one another, which are distributed over the entire flat side 100A are arranged and each encode at least one position. In both cases, the position code pattern 150 can be captured and decoded virtually anywhere on the flat metal product 100. In particular, the position code pattern 150 can still be preserved, for example, on shredded product parts (e.g. scrap cuts) to such an extent that it remains detectable and decodable.

Figure 3 shows a section of the position code pattern 150 on the flat metal product 100. The points P are in an irregular manner Arranged in a grid, i.e. the distances between neighboring points vary. The enlarged section in Figure 1B illustrates this using a virtual regular grid of dotted lines. For example, the points P are never on the intersection points of the virtual grid, but are shifted from the intersection point by a certain distance along one of the grid lines. The displacement from the intersection points of the virtual grid can be the same for all points P.

The value of a point P depends on where the point P is located relative to the virtual grid. In the example shown here, there are four possible positions for a point P. This means that a point P, for example, can be assigned four different values, depending on which grid line and direction it is shifted along.

Figure 3 shows two different partial areas T1, T2 within the position code pattern 150. The partial areas T1, T2 can, for example, overlap one another. Each sub-area T1, T2 of the position code pattern 150 encodes the coordinates of a position on an imaginary surface. In other words, in this example, 16 points are used to encode a position on the imaginary surface. That is, by varying the distances between a plurality of neighboring points P (here, for example, 16 points), a position on the imaginary surface can be clearly encoded. The position code thus forms an imaginary surface defined by all positions of the position code that the position code can encode. Due to the high number of possible combinations of dot grids with varying distances, the imaginary surface can be very large and, for example (e.g. with a position code of 6 × 6 points and 4 values per point) have a total area that depends on the selected grid is several square kilometers, in particular several thousand square kilometers, in particular several million square kilometers in size.

In the in Figure 3 In the example shown, for example, at least two positions on the imaginary surface are uniquely determined by the exemplary partial areas T1, T2 of the position code pattern 150 (one can easily see that significantly more positions can be coded in the section, since many partial areas consist of 16 points in the shown position code pattern 150).

A position code of the form described above is from Scripture US 6,958,747 B2 known, with features of the exemplary position code described there being incorporated into this document by reference. However, according to the present disclosure, other position code patterns from an array of distributed points P may also be used, e.g. position code patterns in which the points P lie on more than two virtual grid intersection lines and/or by more than a single fixed distance along one the grid lines may be shifted and/or a position is encoded by fewer than 16 points. Furthermore, in other examples, the points P can also be shifted relative to virtual reference structures other than a grid, such as a honeycomb structure or an array of circles. In all cases, the position code pattern 150 of a flat metal product 100 uniquely encodes at least one position on the imaginary surface of the position code. Based on this position and information associated with it (e.g. flat metal product ID), the position code pattern 150 can uniquely code the flat metal product 100.

The nominal grid spacing of the arrangement of distributed points P is the grid spacing of the (regular) virtual grid (see e.g Figure 1B ) designated. This grid spacing can be equal to or greater than 0.1 cm, 0.5 cm, 1 cm, 2 cm or 5 cm. This means that the grid spacing can be significantly larger than is the case with known applications of a position code pattern based on a virtual grid.

The position code pattern 150 can be selected such that each of the flat metal products 100 contains at least 10 × 10 points P. Since in the example of a position code made up of 4 × 4 points described above (see, for example, sub-area T1 or sub-area T2) encode a position on the imaginary surface and the sub-areas T1 and T2 (encoding different positions) can be overlapping, a position code can be used Pattern 150 of at least 10 × 10 points can already clearly determine a large number of different positions on the imaginary surface.

The grid spacing of the virtual grid (which corresponds to the average spacing of the points P in the position code pattern 150) should be chosen so that the points P can be detected with the resolution of a measurement system. In addition, a comparatively large grid spacing can enable more robust decoding of the position code based on the captured dot patterns. On the other hand, with large grid spacings, decoding the position code may no longer be possible from a certain degree of shredding of the flat metal product 100 (e.g. scrap parts).

The size of the points P can be approximately the size of the displacement of the points P from the intersection of the lines of the virtual grid are equivalent to. The points P can, for example, have an identical size (eg identical diameter).

In general, in a position code made up of an arrangement of distributed points, each point can be assigned to a nominal position (e.g. a specific intersection of the lines of the virtual grid) and the value of the point can be determined by its position relative to its nominal position. With such a position code, the coordinates of a large number of positions can be encoded. This number can be significantly larger than the number of necessary positions (namely at least one) on a single flat metal product 100. Different information can be assigned to different positions. Redundancy can be created by assigning the same information to different positions (e.g. coded by partial areas T1, T2) of the position code pattern 150 on a specific flat metal product 100 and/or by encoding the same position multiple times in the position code pattern 150 of a specific flat metal product 100 is.

Also disclosed is a method for producing a flat metal product 100, which makes it possible to retrieve information in connection with the flat metal product 100. The method may include providing the flat metal product 100 and generating a position code pattern 150 from an array of distributed points P on at least one flat side 100A of the flat metal product 100. Furthermore, the method can optionally have further manufacturing steps, such as coating a metal strip or a metal circuit board 110 with a coating 120, whereby the position code pattern 150 can be realized, for example, on, in or under the coating 120 (see, for example, Figure 2 ). The (single-layer or multi-layer) coating can be applied 120 can be carried out using a wide variety of methods and coating materials, with reference being made to the above statements to avoid repetition.

Figure 4 illustrates an example of a method for retrieving information associated with a flat metal product 100, the flat side 100A of which is provided with a position code pattern 150 made up of an array of distributed dots P.

The method includes capturing at least a portion of the position code pattern 150 using a reader 410. The reader 410 may optically capture the position code pattern 150. For example, a camera 420 of the reading device 410 can be used for this.

The reading device 410 can be, for example, a smartphone or a tablet computer. It is also possible for a reading device 410 specifically intended for reading the position code pattern 150 to be used, for example a position code pattern scanner 150. Such a scanner can, for example, be installed in a plant for scrapping or recycling scrap from flat metal products 100 .

It is also possible that the reading device 410 does not carry out an optical detection, but rather a detection in another way, such as using magnetic fields or using X-rays or radar radiation. In this case, the position code pattern 150 must be implemented so that it can be detected using these techniques.

At least a portion of the captured position code pattern 150 is further decoded to determine at least a position on an imaginary surface. The decoding can be carried out, for example, using application software (app) 430, which is stored in a memory of the reading device 410. It is also possible for the decoding to be carried out by an external device, for example a computer (not shown), to which the reading device 410 can be connected.

Based on the determined position or positions, information is retrieved that is assigned to the determined position or positions. The information can be retrieved, for example, via a network 450, for example the Internet. The information assigned to the determined position or positions can be stored on a server 460 and accessed via the network 450 via addressing depending on the position or positions determined. The retrieved information can either be transported to the reader 410 or routed to another terminal device (not shown) connected to the network 450.

The information can have a variety of contents. For example, the information retrieved can be information about the flat metal product 100, that is, in particular, product identification data and/or data on the materials and/or their chemical compositions of the flat metal product 100. Furthermore, data from the manufacturing process or even logistics data, installation data or Recycling data of the flat metal product can be 100 contents of information. This and other information can, for example, come from the manufacturer of the flat metal product 100 and/or a logistics company that delivers the flat metal product 100 and/or a construction company that installs the flat metal product 100 or demolished and/or scrapped, retrieved or, if necessary, made available.

The position code can be particularly important in the circular economy for the reuse of scrap parts. Thanks to the unique coding on the flat metal product 100, for example, the steel quality (composition) of the scrap can be clearly identified and can thus be specifically incorporated back into steel production.

Furthermore, scrap components can be clearly assigned to the steel manufacturer thanks to the coding. This means that the steel manufacturer can, for example, contractually secure the return of the scrap when it is sold.

In addition, cross-manufacturer information handling is made possible, for example by allowing information about materials built into flat metal products 100 (e.g. sandwich panels) to be read out at any time and/or recycling information for demolition and/or material separation can be easily provided and/or accessed.

Furthermore, the information can also contain information about the intended use and/or the location of use of the flat metal product 100, which is provided, for example, by a user of the flat metal product 100 (e.g. a customer of the manufacturer). This allows the "information providing functionality" of the flat metal product 100 to be used not only by the manufacturer, but also (or alone) by other people.

For example, facade elements of a building (e.g. a museum) can be used by the user of the building to communicate the facade elements make information available to visitors, for example about the building or its intended use or about the user's offers. For example, in a museum, information about the exhibits could be available to visitors. For a restaurant, the menu could be available, etc.

Thus, a method for providing information in connection with a flat metal product 100 is also disclosed, in which the flat metal product 100 is provided at least on one flat side 100A with a position code pattern 150 made up of an arrangement of distributed points P, wherein detecting and decoding at least one part of the position code pattern 150 enables the determination of a position on an imaginary surface. The method includes providing information that is assigned to a determinable position. This information can be provided, for example, via a computer 470 that can be connected to the network 450 and which enables the information to be entered and/or forwarded to the server 460, for example via the network 450. The server 460 can then - as already described - make this information available to the interested party when information is retrieved.

Claims (18)

Flat metal product which is provided on at least one flat side (100A) with a position code pattern (150) made up of an arrangement of distributed dots (P). Flat metal product according to claim 1, wherein the flat metal product (100) is a metal strip or a metal blank or a component containing at least one metal blank and a further material layer. A flat metal product according to claim 1 or 2, having a coating on the flat side (100A) provided with the position code pattern (150). A flat metal product according to claim 3, wherein the position code pattern (150) is realized in the coating (120). A flat metal product according to claim 3, wherein the position code pattern (150) is applied to the coating (120). Flat metal product according to one of the preceding claims, wherein the dots are applied by printing. Flat metal product according to one of the preceding claims, wherein the flat side (100A) is provided with the position code pattern (150) essentially over its entire surface. Flat metal product according to one of the preceding claims, wherein the arrangement of distributed dots has a nominal grid spacing of equal to or greater than 0.1 cm, 0.5 cm, 1 cm, 2 cm or 5 cm. Flat metal product according to one of the preceding claims, wherein the position code pattern (150) uniquely codes the flat metal product (100). A flat metal product according to any preceding claim, wherein the position code pattern (150) encodes at least one position on an imaginary surface. A flat metal product according to claim 10, wherein the distances between adjacent points vary and the variation in the distances of a plurality of adjacent points uniquely encodes the position on the imaginary surface. Method for retrieving information in connection with a flat metal product (100), which is provided on at least one flat side (100A) of the flat metal product (100) with a position code pattern (150) made up of an arrangement of distributed points, the method comprising: detecting and decoding at least a portion of the position code pattern (150) to determine a position on an imaginary surface; and Retrieve information associated with the discovered location. Method according to claim 12, wherein the detection of the at least part of the position code pattern (150) is carried out optically by means of a camera (420) of a reading device (410). Method according to claim 13, wherein the decoding of the detected part of the position code pattern (150) is carried out using application software (430) of the reading device (410), in particular a mobile device. Method according to one of claims 12 to 14, wherein the information retrieved contains information about the flat metal product or the flat metal product, in particular product identification data and / or data which, in the case of a flat metal product made from a metal strip, are clearly assigned to the original position of the flat metal product in the metal strip, and/or data on the manufacturing process, the materials, their chemical compositions, logistics data, installation data, data regarding the maintenance history, recycling data of the flat metal product (100) or data for marketing purposes. Method according to one of claims 12 to 15, wherein the information retrieved contains information about the intended use and/or location of the flat metal product (100) and/or information provided by the user of the flat metal product (100). Method for providing information in connection with a flat metal product (100), which is provided on at least one flat side (100A) of the flat metal product (100) with a position code pattern (150) made up of an arrangement of distributed points, wherein at least detecting and decoding a part of the position code pattern (150) enables the determination of a position on an imaginary surface, the method comprising:
Providing information that is assigned to a determinable position. The method of claim 17, wherein the information stored on a server (460) and can be accessed via addressing depending on a determinable position via a network (450), in particular the Internet, or is stored in a memory of a reading device (410) for detecting and decoding at least part of the position code pattern (150) and can be retrieved from the memory via addressing depending on a determinable position.

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